KR100306335B1 - Semiconductor integrated circuit device - Google Patents

Abstract

In a macro cell constituting a logic circuit such as a gate array, there has been a problem that it cannot be used as a wiring area because the wiring grating in the horizontal direction is laid out with the first Al wiring.

The interconnection between the PMOS transistors and the NMOS transistors is performed partially through the salicide layer formed with low resistance in the source / drain regions of these transistors, thereby partially replacing the first Al wirings in the intra-cell wirings. As a result, the wiring area can be set in the empty area formed above the salicide layer, thereby increasing the degree of freedom of chip layout.

Description

Semiconductor integrated circuit device {SEMICONDUCTOR INTEGRATED CIRCUIT DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to semiconductor integrated circuit devices such as, for example, gate arrays and embedded cell arrays (ECAs). In particular, macrocells serving as logic circuits such as AND circuits and flip-flop circuits used in the semiconductor integrated circuits are described. (macro cell) and peripheral circuit layout.

Recently, in order to improve the performance of transistors in the process technology, magnetic matching such as TiSi ₂ , CoSi _2, etc., which has reduced resistance by alloying a silicon surface layer with a high melting point metal such as titanium Ti or cobalt Co, etc. Type silicides, or salicides, are becoming popular as semiconductor technologies. In general, the resistance values of the source and drain regions, the well regions, and the like of the field effect transistors alloyed by the formation of the salicide layer are lowered to about 1/10 compared with those produced without applying the salicide method. Therefore, new technology improvement utilizing the characteristics is expected.

20 is a block diagram illustrating a master chip image of a conventional front-side gate array. In the figure, 121 and 124 are PMOS transistor groups, 122 and 123 are NMOS transistor groups, and 125 are peripheral circuits (I / O interfaces). In addition to the gate array, there are channel fixed type, complex type, QTAT, and the like, but here, the front-end type will be described in terms of integration and device performance.

FIG. 21 shows a basic cell in the cell area in FIG. 20 for constructing a logic circuit with a gate array, an ECA, etc., where 121 is a basic cell, 122 is a PMOS transistor, and 123 is shown. NMOS transistors, 124, 125, and 126 are gates, source and drain regions and well regions of the PMOS transistors, and 127, 128, and 129 are gates, source and drains of the NMOS transistors, respectively. The regions and well regions, (10a (1)) to (10a (n)) are wiring gratings in the horizontal direction, and 11a (1) to (11a (n)) are wiring gratings in the vertical direction. Then, a macro cell is laid out using a basic cell arranged in an array shape, and a semiconductor integrated circuit having a certain logic function is formed by arranging and wiring the macro cell.

FIG. 4 is a layout diagram when a three-input AND circuit is constructed of, for example, the conventional gate array, ECA, etc. shown in Japanese Patent Laid-Open No. 7-7141, and FIG. 3 is a circuit diagram thereof. In the figure, reference numeral 1a denotes a power supply wiring VDD, 1b a ground wiring GND, 3 a contact, 1c a first Al wiring, A, B, and C are three input AND circuits, respectively. The input terminal, Y, is its output terminal.

Normally, the layout of the macro cell is a logic function by electrically connecting the gate, source / drain region and well region of the basic cell using the contact 3 and the first Al wiring 1c as shown in FIG. It is configured to have. At this time, the contacts are arranged as possible on the source / drain region and the well region of the transistor, and the parasitic resistivity of the source / drain region and the well region is reduced by electrically connecting them with the first Al wiring. In addition, in order to electrically connect the macro cell, a via of the second Al wiring and the connection element may be used in the longitudinal direction.

The semiconductor integrated circuit device is constructed by arranging and wiring logic circuits such as an AND circuit, a flip-flop circuit, and the like laid out by the above method. At this time, the input / output connection pins of the macro cells are electrically connected to each other via vias, contacts, and the like using first Al wiring for the horizontal wiring and second Al wiring for the vertical wiring. .

12 is a block diagram showing a connection between a transistor such as a conventional gate array, an ECA, and a power supply and ground wiring, and FIG. 13 is a cross-sectional view taken along the line III-III of FIG. In the figure, 84a and 84b are first Al wirings, 83 are contacts, 81a are power supply wirings, 81b are ground wirings, and these are usually made of metal wiring such as aluminum. In general, in the CM0S gate array, the PM0S transistor and the NMOS transistor are adjacent to each other, one side of the PMOS transistor includes a power supply wiring 81a composed of a first Al wiring, and one side of the NMOS transistor has a ground wiring 81b. The power supply wiring 81a is connected to the power supply of the chip at both ends of the chip, and the ground wiring 81b is connected to the ground of the same chip at both ends of the chip.

When the source region of this PMOS transistor is connected to a power supply, it connects from the power supply wiring 81a to the source region of a PMOS transistor in the some contact 83 through the 1st Al wiring 84a. On the other hand, when the source region of the NMOS transistor is grounded, the contact 83 is connected to the source region of the NM0S transistor through the first Al wiring 84b from the ground wiring 81b.

In the conventional layout of a semiconductor integrated circuit such as a gate array or an ECA, the three-input AND circuit shown in Figs. 3 and 4 is taken as an example, and the wiring lines in the horizontal direction are all laid out as the first Al wiring. For this reason, in the 1st Al wiring, the horizontal wiring grating cannot be used as a wiring area | region. In addition, since the power supply wiring is wired with the first Al wiring above and below the macro cell, there is a restriction that the signal wiring in the vertical direction must use a wiring layer such as a second Al wiring other than the first Al wiring. That is, in the layout of the semiconductor integrated circuit device, since the macro cell region and the wiring region are required separately, particularly in a complicated integrated circuit, there are problems such as a large wiring region and a large semiconductor chip area.

On the other hand, the power and ground wirings are laid out as the first Al wirings as shown in Figs. 12 and 13, but a large number of contacts 83 are used for connection with these well regions in order to lower the resistance. There have been problems such as a need to provide and a problem that the aluminum constituting the first Al wiring may be disconnected during operation of the device under the influence of electromigration.

Disclosure of Invention An object of the present invention is to solve the above-mentioned problems. A semiconductor integrated circuit device which facilitates the layout of a macro cell or a peripheral circuit by using a salicided source / drain region and a well region as part of a wiring layer. And a layout method thereof.

1 is a layout diagram for describing Embodiment 1 of the present invention;

2 is a cross-sectional view taken along the line I-I of FIG.

3 is a circuit diagram of the layout of FIG. 1;

Figure 4 is a layout diagram according to the prior art,

5 is a layout diagram for describing a second embodiment of the present invention;

Figure 6 is a layout diagram according to the prior art,

7 is a circuit diagram of the layout of FIG. 5;

8 is a layout diagram for describing a third embodiment of the present invention;

9 is a circuit diagram of the layout of FIG. 8;

10 is a layout diagram for explaining a fourth embodiment of the present invention;

11 is a cross-sectional view taken along the line II-II of FIG. 10;

12 is a layout diagram according to the prior art,

FIG. 13 is a cross-sectional view taken along line III-III of FIG. 12;

14 is a layout diagram for describing a fifth embodiment of the present invention;

15 is a layout diagram for explaining a sixth embodiment of the present invention;

16 is a layout diagram according to the prior art;

17 is a circuit diagram of the layout of FIG. 16;

18 is a layout diagram for explaining another preferred embodiment of the sixth embodiment of the present invention;

19 is a layout diagram according to the prior art;

20 is a block diagram showing a master chip image of a conventional front-side gate array;

FIG. 21 is a diagram of a basic cell for constructing a conventional logic circuit; FIG.

FIG. 22 is a circuit diagram of the basic cell of FIG. 21;

Explanation of symbols for the main parts of the drawings

1a, 1d, 21a-21c, 31a-31c, 81a, 81b; 1st Al wiring (conductive wiring, 1st conductive wiring)

1b; 1st Al wiring (2nd conductive wiring)

1c; 1st Al wiring (3rd conductive wiring)

2a. 2b, 22a, 22b, 32a, 32b, 82a, 82b, 92a, 92b, 102a, 102b, 106a to 106c; Salicided source / drain region (silicide layer)

93a, 93b; Gate of PMOS transistor

93c, 93d; Gate of NMOS Transistor

82c, 102c; Salicided Power Wiring (First Power Wiring)

82d, 102d; Salicided Ground Wiring (Second Power Wiring)

94a-94e, 95a-95f, 112, 115-117; Signal wiring

95g, 95h, 10la, 10lb, 101c; Power wiring (first power wiring)

95i, 95j; Ground wiring (second power wiring)

24a, 24b, 34; Second Al wiring (fourth conductive wiring)

25a-25d; Via

3a, 3b, 3d, 23a, 23b, 33a, 33b, 83; Contact

36a, 36b, 36c, 36d, 36e, 36f; Wiring grid

4 ; Other signal wiring using the first Al wiring

5; Field oxide

6; Interlayer insulation film

A, B, C, S; Input terminal

Y; Output terminal

The semiconductor integrated circuit device according to the first aspect of the invention has a first field effect transistor group connected to a first power supply wiring arranged in one direction and connected to a first power supply wiring on a silicon substrate surface, the first potential being arranged side by side And a second field effect transistor group connected to a second power supply wire for supplying a second lower potential, and conductive wiring for connecting these transistors to each other, and at least one transistor group of the first and second field effect transistor groups. The silicide layer is formed in the source / drain regions of each transistor of the transistor, and the wiring layer is formed by connecting it with the conductive wiring, and the signal wiring by the conductive wiring can be arranged above the wiring layer.

The semiconductor integrated circuit device according to the second aspect of the invention has a first field effect transistor group connected to a first power source wiring arranged in one direction and connected to a first power supply wiring on a silicon substrate surface, and arranged in parallel with this than the first potential. A second field effect transistor group connected to a second power supply wiring for supplying a low second potential, and a first transistor selected from the first field effect transistor group and a second transistor selected from the second field effect transistor group; The first conductive wiring, the silicide layer formed in at least one of the source and the drain of the first and second transistors, and the second conductive wiring connected to the silicide layer are provided.

The semiconductor integrated circuit device according to the third aspect of the invention has a first power supply wiring connected to a first power supply, a first field effect transistor group arranged in one direction, a first power supply wiring, and a first electric field on a silicon substrate surface. A first conductive wiring connecting the first transistor selected from the effect transistor group to each other, a second power supply wiring connected with a second power supply that supplies a lower potential than the first power supply, and a first field effect transistor arranged in parallel 2nd field effect transistor group, 2nd power supply wiring, and 2nd electroconductive wiring which connects the 2nd transistor selected from the 2nd field effect transistor group with each other, and the 1st and 2nd power supply wiring which contact | connects a well area | region, and 1st and A silicide layer is formed on at least part of the source and drain of the second field effect transistor group, and the silicide layer is connected to the conductive wiring. To form a W wiring.

The semiconductor integrated circuit device according to the fourth aspect of the present invention provides a semiconductor integrated circuit device comprising: at least a portion of a first conductive wiring connected to a power source, a field effect transistor group arranged in one direction, and a source / drain selected from a field effect transistor group on a silicon substrate surface; A first transistor having silicide formed thereon, second and third transistors in which a source and a drain adjacent to the first transistor are connected to the first conductive wiring, second conductive wiring using a part of the silicide as the wiring layer, and an upper portion of the wiring layer. It is provided with the 3rd electroconductive wiring formed in the.

A semiconductor integrated circuit device according to a fifth aspect of the invention has a first power supply wiring connected to a first power supply, a first field effect transistor group arranged in one direction, a first power supply wiring, and a first electric field on a silicon substrate surface. A first conductive wiring connecting the first transistor selected from the effect transistor group to each other, a second power supply wiring connected with a second power supply that supplies a lower potential than the first power supply, and a first field effect transistor arranged in parallel A second field effect transistor group, a second power line and a second conductive line connecting the second transistor selected from the second field effect transistor group to each other, wherein the first and second power line and the first power line are in contact with the well region. The silicide layer is formed in the source and drain of the first and second field effect transistor groups, and the silicide layer is connected to the conductive wiring. To form a seoncheung.

Example

Hereinafter, an embodiment of the present invention will be described.

(Example 1)

1 is a layout diagram of a three-input AND circuit using a basic cell of a salicided transistor structure according to Embodiment 1, FIG. 2 is a sectional view taken along line II of the circuit layout of FIG. 1, FIG. 3 is a circuit diagram thereof, and FIG. Is a layout diagram according to the prior art. In the figure, reference numerals 1a and lb denote first Al wirings, power supply wirings, ground wirings, and 2a and 2b, respectively, with salicided source and drain regions, and 3a to 3d. The contact (4) is another signal wiring using the first Al wiring, (5) is a field oxide film, (6) is an interlayer insulating film, A, B and C are input terminal gates, and Y is an output terminal. Each of the source and drain regions includes a plurality of wiring gratings, that is, grids, and four wiring gratings are arranged side by side in the longitudinal direction in FIG. 1 (see FIG. 8).

Here, salicide refers to a high melting point metal silicide formed in a self-matching type, and is made low resistance by heat treatment or the like. That is, in order to form this, a high melting point metal layer such as cobalt, titanium, molybdenum, tungsten, or the like is formed in the active region of the silicon substrate, followed by heat treatment to make an alloy such as silicide to lower its resistance, Unnecessary portions can be removed using photolithography or the like.

Gate arrays, ECAs, etc. standardize and library relatively simple and small-scale logic functions such as NAND, NOR, and F / F called cells, and design chips by combining them. In particular, the front-mounted gate array includes a mega cell. In Fig. 1, a PMOS transistor and an NMOS transistor are formed adjacent to each other in the horizontal direction. Adjacent drains are separated by a gate width and separated from each other.

Next, the operation will be described.

Since the source / drain regions 2a and 2b reduced in resistance to about 1/10 by a salicide by a high melting point metal can be substituted for the first Al wiring, the contacts 3a, The source / drain between (3b) and (3c) and (3d) can be electrically connected, that is, energized via the salicide layer passing through the lower portion of the interlayer insulating film 6. With this configuration, since there is a space of one wiring grating between the contacts 3a, 3b and 3c, 3d, another signal wiring using the first Al wiring can pass therethrough. . Therefore, when this empty wiring grating is used in the chip layout, the wiring to be used for the wiring region in the horizontal direction can be formed.

As described above, according to the first embodiment, since the salicided source / drain layer can be useful as part of the first Al wirings, other wirings such as signal wirings can be disposed in the basic cell. Therefore, there is an effect of facilitating the chip layout of the semiconductor integrated circuit.

(Example 2)

5 is a layout diagram of a selector circuit according to Embodiment 2, FIG. 7 is a circuit diagram of this selector circuit, and FIG. 6 is a layout diagram according to the prior art. In the figure, reference numerals 21a to 21c denote first Al wirings, power supply wirings, ground wirings, 22a and 22b, respectively, and the salicided wiring source / drain regions, and 24 denotes second Al wiring. , (25a) to (25d) are vias that are conductive connecting elements. The wiring layout method of FIG. 5 is the same as the method described in Example 1, and a part of the drain region 22a alloyed by salicide formation by the electrical connection between 23a and 23b is used as the wiring layer.

Next, the operation will be described.

For example, between the contacts 23a and 23b of FIG. 5, a part of the source / drain region which becomes low resistance by salicide is covered by the first Al wiring, and a separate wiring is passed through the empty space. You can. In addition, when the salicide layer is used as the wiring layer, the contact is finished with at least two.

On the other hand, in the prior art, in order to be connected to the source / drain region, since it is high resistance, several contacts must be provided to reduce the resistance, and it is inevitable that the area occupied by the first Al wiring will be enlarged. As can be seen, the vias 25a to 25d connecting the first Al wiring and the second Al wiring and the second Al wiring 24a and 24b are often used. In the layout of the second embodiment, the contact is minimized by utilizing the salicide layer and the second Al wiring can be omitted, and the vertical wiring can be used to wire the macro cell on the signal wiring during chip layout. Since the grating can be secured, the chip area of the semiconductor integrated circuit can be reduced.

As described above, according to the second embodiment, the macro cell is laid out using the basic cell of the salicided transistor structure, and in particular, the signal wiring is wired in the macro cell by using the drain region of the transistor as the wiring layer. A wiring grating can be obtained. Moreover, this wiring grating can be used as a wiring area of a chip layout of a semiconductor integrated circuit composed of a plurality of macro cells, whereby wiring arrangement can be efficiently performed, and the chip area of the semiconductor integrated circuit can be reduced. Of course, it goes without saying that there is an effect of facilitating the layout of the macro cell.

(Example 3)

8 is a layout diagram of a two-input NAND circuit according to the third embodiment, and FIG. 9 is a circuit diagram thereof. In the figure, (31a) to (31c) are first Al wirings, (32a) and (33b) are salicided drain regions, (33a (y1)) and (33b (y2)) are contacts, (34) Is a second Al wiring, 36a to 36f are wiring gratings included in each of the salicided drain, A and B are input terminals, and Y is an output terminal.

Next, the operation will be described.

According to the third embodiment, the layout relating to the definition of the pins of the output terminal Y of the two-input NAND circuit is first used for the contact 33a (in order to use the drain region reduced in resistance by salicide) as the wiring layer. yl)) and 33b (y2) to connect the first Al wiring, which is the output terminal Y, to the salicided drain regions 32a and 32b, and then to the second Al to be used for the wiring between the macro cells. The pin of the wiring is defined in any one of the contacts 36a to 36f. In this way, when the input and output pins of the macro cell having a logic circuit such as a two-input NAND circuit are defined, the area where signal wiring connections of the input and output pins can be increased. In addition, the degree of freedom in layout is increased by allowing other signal wires to pass through the empty area. That is, signal wiring between macro cells becomes easy, which contributes to shortening of chip layout time, reduction of chip area, and the like.

Referring to FIG. 8 as an example, the wiring grating point is defined by defining the wiring grating 36a as the pin of the second Al wiring and setting the contacts 33a (yl) and 33b (y2) to the output terminal Y. It is not necessary to pass the first or second Al wirings for the output terminals to (36b), (36c) and (36d) to (36f), and it can be used for layout of other signal wirings and the like. On the other hand, according to the definition of the pin of the prior art, since the second Al wiring must be connected to any of the contacts 33a (yl) and 33b (y2), the wiring gratings 36a to 8 are taken as an example. The wiring lattice group of any one of (36c) and (36d) to (36f) is limited by the degree of freedom under the influence of the layout of the first or second Al wiring for the output terminal Y at least.

As described above, according to the third embodiment, the definition of the pin of the macro cell is also given to the salicided drain region, so that the signal wirings between the macro cells can be easily connected, and the chip layout time can be shortened and integrated. The chip area of the circuit can be reduced.

(Example 4)

Fig. 10 is a layout diagram showing a transistor / wiring configuration of a gate array, an ECA, etc. according to the fourth embodiment, Fig. 11 is a sectional view taken along the line II-II of Fig. 10, Fig. 12 is a gate array, ECA, etc. according to the prior art. 13 is a cross-sectional view taken along the line III-III of FIG. 12. In the figure, 81a is a power supply wiring, 81b is a ground wiring, and in this case is formed of metal wiring such as aluminum, 82a, 82b is a salicided source region, and 82c is a well region. Power source wiring by salicide formation, 82d is a ground wiring connection by salicide of a well region, 83 is a contact, 84a, 84b is 1st Al wiring.

12, in a conventional gate array, a PMOS transistor and an NMOS transistor are adjacent to each other, and one side of the PMOS transistor has a power supply wiring 81a composed of first Al wiring, and one side of the NMOS transistor. There is a ground wiring 81b. The power supply wiring 81a is connected to the chip power supply at both ends, and the ground wiring 81b is similarly connected to the chip ground at both ends of the chip. When the source region of the PM0S transistor is connected to the power supply, the contact 83 is connected to the source region of the PMOS transistor via the first Al wiring 84b in the power supply wiring 81a. On the other hand, when the source region of the NMOS transistor is grounded, the contact 83 is connected to the source region of the NMOS transistor via the first Al wiring 84a in the ground wiring 81b.

On the other hand, as shown in Figs. 10 and 11, in the fourth embodiment, the n ⁺ well region 82c connected to the power supply, the p ⁺ well region 82d connected to the ground, the NMOS transistor and the PM0S transistor The silicon surfaces on the source regions 82a and 82b are salicided and alloyed. In addition, the power supply and ground wiring by the 1st Al wiring like FIG. 12 which is a prior art example are not used, and alloying parts 82c and 82d which were made by salicided the well area instead were used as power supply wiring and ground wiring, respectively. Substitute. At this time, the contact group 83 which connects the power supply wiring 81a and n ⁺ well area | region of FIG. 12 of a conventional example, and the contact group 83 which connects the p ⁺ well area | region with the ground wiring 81b are unnecessary. This is because the power supply wiring 82c and the ground wiring 82d by salicide are in direct contact with the well region corresponding to the well region corresponding to the power supply wiring 81a and the ground wiring 81b in FIG. 12.

10 and 11, when the power source potential VDD is supplied to the source region of the PMOS transistor, the PMOS transistor is provided through the contact 83 and the first Al wiring 81b in the power source wiring 82c formed by salicided the well region. Connect to the source area of. On the other hand, when the ground potential GND is supplied to the source region of the NMOS transistor, the source wiring of the NMOS transistor is connected to the source region of the NMOS transistor through the contact 83 and the first Al wiring 81a in the ground wiring 82d formed by salicided the well region. Connected.

Next, the operation will be described.

According to the wiring structure of the fourth embodiment, in order to use the salicided power wiring and ground wiring, the power supply and ground wiring do not have to be drawn out from the first Al wiring. The wiring for connection between the cells drawn out of the Al wiring can be used as a region for drawing out the wiring. Therefore, the chip size can be made small by using the area | region where only the 2nd Al wiring was wired as the wiring area | region which connects between cells until now is used as the wiring area which arrange | positioned 1st Al wiring and 2nd Al wiring. have.

In addition, when the power supply and the ground wiring are drawn out from the first Al wiring as in the conventional example, as shown in (83) of FIG. 12, a large number of contacts 14 are formed between the well regions and the first Al wiring. You must install it. This is because if the contact 83 is small, the resistance between the well region and the first Al wiring becomes large. However, in the case where the well region is salicided, the well region does not need to be connected by contact since the surface is directly alloyed and connected. For this reason, the manufacturing process of wiring a power supply and a ground wiring with a 1st Al wiring, and the manufacturing process of providing a contact to a power supply and ground wiring can be reduced.

In addition, when the power supply and the ground wiring are drawn out from the first Al wiring, aluminum may be disconnected during operation due to the occurrence of electromigration. However, when the salicided power supply wiring and the ground wiring are used, such disconnection is performed. The likelihood of the change can be reduced, thereby improving reliability.

As described above, according to the fourth embodiment, as the wiring region for connecting the cells, a region in which only the second Al wiring can be wired can be used as the wiring region in which the first Al wiring and the second Al wiring are arranged. Therefore, the degree of integration is improved, thereby reducing the chip size. In addition, in the case where the well region is alloyed by salicide, since it is directly connected, there is no need to connect from the contact. Therefore, a contact is made to the manufacturing process for wiring the power supply and the ground wiring with the first Al wiring, and the power supply and the ground wiring. There is an effect that can reduce the manufacturing process to install the. In addition, the use of the salicided power supply wiring and ground wiring reduces the possibility of disconnection due to electromigration of aluminum, thereby improving the reliability.

(Example 5)

FIG. 14 is a layout diagram according to Embodiment 5, in which reference numeral 91a denotes a power supply wiring which salicides a well of a PMOS transistor, 91b denotes a ground wiring which salicided a well of an NMOS transistor, and 92a. Is the region where the source region of the PMOS transistor is salicided, 92b is the region where the source region of the NMOS transistor is salicided, (93a), (93b) is the PMOS transistor, (94a) (94e), (95a). ) To (95j) are signal wires, (95g) and (95h) are connected to a power supply, and (95i) and (95j) are connected to ground.

In general, in the SOG (Sea of gate) of the gate array, the transistor is arranged on the entire surface of the chip in advance to prepare a master chip, and the cell area and the wiring area are defined and used during layout. In this case, the transistor in the wiring area is not used, and this area is used only as the wiring area by the first Al wiring and the second Al wiring.

By performing salicideization in the source / drain regions of all transistors in the chip at the time of manufacturing the master chip, not only the cell region but also the source / drain regions of the unused transistors in the wiring region are also salicide. Make up.

When the inter-cell wiring 94b and the inter-cell wiring 94c are connected using this salicided source / drain region in the region a, the gates 93a and 93b of the PMOS transistors in the wiring region are connected. It connects to the power supply wiring 91a via the wiring 95g. The signal wiring 94b is connected to the source (drain) region (region a) of the transistor having the gate 93b by using a contact. Since the source (drain) region (region a) of the transistor is salicided and alloyed, the inter-cell wiring 94b and the inter-cell wiring 94c can be connected in the region a.

When the inter-cell wiring 94d and the inter-cell wiring 94e are connected using this salicided source / drain region in the region b, the gates 93c and 93d of the NMOS transistors in the wiring region are connected. It is connected to the ground wiring 91b via the signal wirings 95i and 95j. Further, the signal wiring 94d is connected to the source (drain) region (region b) of the transistor having the gate 93d by using a contact. The signal wiring 94e is connected to the source (drain) region (region b) of the transistor having the gate 93d by using a contact. Since the source (drain) region (region b) of the transistor is salicided and alloyed, the inter-cell wiring 94d and the inter-cell wiring 94e can be connected in the region b.

Next, the operation will be described.

As shown in Fig. 14, the gate array transistor is configured in the order of a PMOS transistor, an NMOS transistor, an NMOS transistor, and a PMOS transistor. In addition, the power supply wiring 91a is always formed near the PMOS transistor in the cell region, and the ground wiring 91b is always formed near the NMOS transistor. That is, PM0S transistors are necessarily formed in both neighbors of the power supply wiring, and NMOS transistors are necessarily formed in both sides of the ground wiring.

First, the part of area a is demonstrated. The transistor in the region a is in the wiring region and is not normally used. Here, the gates 93a and 93b of the PMOS transistor are connected to the power supply wiring 91a by using the wirings 95g and 95h, so that the gates 93a and 93b of the PMOS transistor are "L". By taking the potential of, region c and region a are electrically open. Likewise, regions a and d are electrically open. Therefore, the influence of the electric potential of the electric signal of the area a has only the area a.

In the case of using the transistor structure of the fifth embodiment, since the drain / source region of the transistor is salicided and alloyed, the portion of the region a can be used as the third wiring layer. In the example of FIG. 14, since there are the signal wiring 96a and the first Al wiring 95b of the other wiring of the same layer, it cannot be connected by the conventional art so far, but by applying the transistor structure shown above In the region a, the wiring 94a and the wiring 94c can be electrically connected.

Next, the part of area b is demonstrated. The transistor in the region b is in the wiring region and is not normally used. Here, the gates 93c and 93d of the NMOS transistor are connected to the ground wiring 91b by using the signal lines 95i and 95j, so that the gates 93c and 93d of the NMOS transistor are "H". By taking the potential of, the region e and the region b are electrically open. Likewise, region b and region f are electrically open. Therefore, the influence of the electric potential of the electric signal of the area b has nothing but the area b.

In the case where the transistor structure of the fifth embodiment is used, since the drain and source regions of the transistor are salicided and alloyed, the portion of the region b can be used as the third wiring layer. When the wiring 94d and the wiring 94e are connected in the region b, they are connected by the second Al wiring. In the embodiment of Fig. 14, the signal wiring of the wiring 96b of the other wiring of the same layer and the first Al wiring ( 95e) cannot be connected by the conventional art so far, but by applying the structure shown above, the wiring 94d and the wiring 94e can be electrically connected in the region b.

As described above, according to the fifth embodiment, even when there are the signal wirings 96a and 96b by the second Al wiring, the wiring 94b is provided in the region a (region b). And 94d can be connected to the wirings 94c and 94e, respectively. Therefore, the chip size has been increased since it had to be wired using other areas until now, but the chip size is reduced by using the salicided source (drain) region of the transistor which has not been used so far as the wiring layer. It can work.

(Example 6)

FIG. 15 is a layout diagram according to the sixth embodiment, FIG. 16 is a layout diagram according to the prior art, and FIG. 17 is a circuit diagram thereof. In the figure, 102a and 102b are salicided source regions, 102c and 102d are salicided wiring layers of well regions, respectively, supplying a power source potential VDD and a ground potential GND, and (10la). ) To 101c are first Al wirings, and 106a to 106c are salicided source regions.

In the wiring structure of the conventional example of FIG. 16, the first Al wirings 10la to 101c are used for supplying power to the source region of the PMOS transistor in the power supply wiring 102c. Since the first Al wirings 10la to 101c are adjacent to each other, no empty area is generated inside the cell. On the other hand, in the wiring structure of the layout of FIG. 15 according to the sixth embodiment, the power supply wiring 102c is connected to the source region 106a of the PMOS transistor via the first Al wiring 10ld via a contact. For this reason, a power supply potential is supplied to the source region 106a of the PMOS transistor.

Since the source region 106a is salicided to have low resistance, it can be used as a substitute for metal wiring. Therefore, the first Al wirings 10la and 10lb are connected via the source region 106a of the alloyed transistor. The first Al wiring 10lb is partially connected by contact holes in the source regions 106b and 106c of the PMOS transistor, but the source regions 106b and 106c are also salicided and alloyed, respectively. Therefore, the power supply is connected to the entire surface of each of these source regions 106b and 106c. Therefore, a power supply potential can be supplied to the source regions 106b and 106c of the PMOS transistor.

Next, another preferred embodiment of the sixth embodiment will be described.

Fig. 18 is a layout diagram according to the present preferred embodiment, and Fig. 19 is a layout diagram according to the prior art, in which reference numeral 111 denotes a ground wiring which salicided a well of an NMOS transistor; The wirings for supplying the ground potential, 112, 115 to 117 are signal wires, 118 are connection points, and A and B are NMOS transistors.

First, according to the layout of the prior art shown in FIG. 19, the gate potential of the NMOS transistor A is dropped to the ground level by the wiring 113, so that the source region and the drain region of the NMOS transistor A are electrically open. have. The wiring 114 is a wiring for grounding the source region of the NMOS transistor, and the wiring 115 is a wiring connected to the drain region of the NMOS transistor. In addition, although the wiring 112 is a wiring connected to the gate of the NMOS transistor B, since the wiring 116 of the same layer exists, it cannot connect to the connection point 118, and it has no choice but to bypass the connection point 118 for wiring. As a result, since the wiring area in a cell is used, it cannot be wired using the wiring of the same layer, when it wants to pass the wiring which crosses a cell.

On the other hand, according to the preferred layout of FIG. 18, the salicided and alloyed source region of the NMOS transistor B adjacent to the wiring 114 is coupled at the contact hole, and the salicide of the wiring 113 and the NMOS transistor B is formed. When the alloyed source region is coupled at the contact hole, the wiring 114 and the wiring 113 are electrically coupled via the alloyed source region of the NMOS transistor B. At the same time, the source region of the NMOS transistor B can be grounded. Since the wiring 113 is connected to the gate of the transistor A, the gate of the NMOS transistor A can be grounded. For this reason, since the part of the wiring 113 of FIG. 19 laid out in the prior art is unnecessary, the wiring 112 of FIG. 18 can be wired in a straight line, and as a result, the wiring 112 in FIG. It is also possible to draw out the wiring 117 across the cell.

The power supply wiring of the prior art was taken directly from the power supply 102c as shown in FIG. 16. However, according to the sixth embodiment and the preferred embodiment, the power supply is saved in the region 106a of FIG. It can be taken in the portion of the source region of the sided transistor. Therefore, as shown in FIG. 15, the area | region which makes the wiring which connects between cells to the internal area | region of a cell can be extended. For this reason, the area | region which could not be used so far can be used for wiring, and there exists an effect which can reduce a chip size.

Further, even if only the inside of the cell is considered, since the power wirings 10lb, 101c, etc. are lost, the above-described region can be used for the arrangement of the signal wiring inside the cell, thus increasing the freedom of wiring in the cell. There is an effect that the cell size can be reduced. In addition, since a circuit is a collection of cells in a gate array, when the cell size is reduced, the chip size can be reduced.

In the case where the conventional technique is used, when power is supplied to the source region to which the wirings 10la to 101c are connected in Fig. 16, the wirings 10la to 10c are used. According to this, only the two wirings of the wiring 10ld and the wiring 10le of FIG. 15 can supply power to the source region. Therefore, since the number of wirings can be reduced, the cell size can be made small, which leads to an effect of reducing the chip size.

As described above, according to the first aspect of the invention, a wiring layer made of silicide is formed in the source and drain regions of each transistor of the first and second field effect transistor groups, and contacts are formed at random intervals in the wiring layer to form conductive wiring and Since it is comprised so that a connection may be made, new electroconductive wiring can be arrange | positioned in the empty area | region between these contacts. Therefore, since this empty area can be set as a wiring area in the chip layout, the layout wiring can be efficiently executed so that signal wiring and the like can pass therethrough, thereby reducing the chip area of the semiconductor integrated circuit device. have.

According to the second aspect of the present invention, since the first conductive wiring and the second conductive wiring are connected to each other via silicide layers formed in the source and drain of the first and second transistors, the degree of freedom of the connection is increased, and thus the macrocell and the like can be entered. The definition of the output pins is easy, which reduces the chip layout time and reduces the chip area of the integrated circuit.

According to the third aspect of the present invention, since the silicide layer formed on the source and drain of the first and second power supply wirings and the first and second field effect transistor groups in contact with the well region is configured to be connected to the first and second conductive wirings, Since these conductive wirings can be directly connected via the silicide layer, separate signal wirings can be arranged in this surrogate region, thereby facilitating the layout and contributing to the reduction in chip size. In addition, the silicide layer has a low resistance as compared with the case where a contact such as a metal is sandwiched between the silicon surfaces so as to be in close contact with the silicon surface, thereby reducing the number of contacts. In addition, since the occupied area of metals such as aluminum becomes small, there is an effect that the disconnection due to the electromigration phenomenon is less likely to occur.

According to the fourth aspect of the present invention, silicide is formed in the source and drain of the first transistor, and the source and drain of the neighboring second and third transistors are at the power source potential. In the relationship of can be configured to be electrically open. Thus, the electrical signal passing through the silicide portion of the second conductive wiring is not affected by the second and third transistors. Therefore, with such a structure, another third conductive wiring or the like can be arranged in the unused space formed above the silicide portion, which contributes to the reduction in chip size.

According to the fifth aspect of the invention, a silicide layer is formed in the source and drain of the first and second power supply wirings and the first and second field effect transistor groups in contact with the well region, and the silicide layer is connected to the conductive wiring to form a wiring layer. Since the power supply wiring is salicided with the well and completed without using a metal wiring layer such as aluminum, the use of this empty area can be efficiently used to increase the degree of freedom of wiring layout and reduce the chip size. It can work.

Claims (4)

A silicon substrate having a surface, An electrically insulating layer on the surface, First and second power wirings provided substantially parallel to the first direction on the electrically insulating layer; A first field effect transistor group arranged parallel to the first direction on the surface and connected to the first power supply wiring for supplying a first potential, each having a source region and a drain region; A second field effect transistor group arranged in parallel to the first direction and connected to the second power supply wiring for supplying a second potential lower than the first potential, each having a source region and a drain region; An electrically conductive interconnect wiring provided on said electrically insulating layer and interconnecting said first and second field effect transistor groups through said electrically insulating layer through said surface; Is provided on the electrically insulating layer so as not to be connected to the first and second field effect transistor groups, at least a portion of which is parallel to the first direction and disposed across one of the first and second field effect transistor groups. Signal wiring located between the first and second power wirings Including, In at least one of the first and second field effect transistors, the source region and the drain region of each transistor include a refractory metal silicide layer fabricated with low resistance by heat treatment, and the refractory metal silicide layer comprises the electrically conductive interconnects. A semiconductor integrated circuit device connected to a connection wiring. The method of claim 1, A plurality of wiring grid dots provided in the source and drain regions of each of the field effect transistors, used as contacts, and arranged along a direction perpendicular to the first direction, And the refractory metal silicide layer is connected to at least two wiring grid dots of the plurality of wiring grid dots. The method of claim 1, The electrically conductive interconnect wiring is connected to a first electrically conductive wiring for connecting a first transistor selected from the first field effect transistor group to a second transistor selected from the second field effect transistor group, and the refractory metal silicide layer. A semiconductor integrated circuit device comprising a second electrically conductive wiring. The method of claim 1, And said interconnect wiring is not electrically connected to said signal wiring in said first and second field effect transistor groups.